• DocumentCode
    766260
  • Title

    Individual time-dependent spectral boundaries for improved accuracy in time-frequency analysis of heart rate variability

  • Author

    Goren, Yael ; Davrath, Linda R. ; Pinhas, Itzhak ; Toledo, Eran ; Akselrod, Solange

  • Author_Institution
    Abramson Center for Med. Phys., Tel-Aviv Univ., Tel Aviv, Israel
  • Volume
    53
  • Issue
    1
  • fYear
    2006
  • Firstpage
    35
  • Lastpage
    42
  • Abstract
    Heart rate variability (HRV) is a major noninvasive technique for evaluating the autonomic nervous system (ANS). Use of time-frequency approach to analyze HRV allows investigating the ANS behavior from the power integrals, as a function of time, in both steady-state and non steady-state. Power integrals are examined mainly in the low-frequency and the high-frequency bands. Traditionally, constant boundaries are chosen to determine the frequency bands of interest. However, these ranges are individual, and can be strongly affected by physiologic conditions (body position, breathing frequency). In order to determine the dynamic boundaries of the frequency bands more accurately, especially during autonomic challenges, we developed an algorithm for the detection of individual time-dependent spectral boundaries (ITSB). The ITSB was tested on recordings from a series of standard autonomic maneuvers with rest periods between them, and the response to stand was compared to the known physiological response. A major advantage of the ITSB is the ability to reliably define the mid-frequency range, which provides the potential to investigate the physiologic importance of this range.
  • Keywords
    electrocardiography; medical signal processing; neurophysiology; pneumodynamics; time-frequency analysis; autonomic nervous system; body position; breathing frequency; heart rate variability; individual time-dependent spectral boundaries; time-frequency analysis; time-frequency approach; Autonomic nervous system; Cardiology; Fluctuations; Hafnium; Heart rate; Heart rate variability; Noninvasive treatment; Physics; Steady-state; Time frequency analysis; Continuous wavelet transform; individual spectral bands; time-dependent spectral bands; time-frequency decomposition; Algorithms; Diagnosis, Computer-Assisted; Electrocardiography; Fourier Analysis; Heart Rate; Humans; Pattern Recognition, Automated; Posture; Reproducibility of Results; Respiratory Mechanics; Sensitivity and Specificity; Time Factors;
  • fLanguage
    English
  • Journal_Title
    Biomedical Engineering, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9294
  • Type

    jour

  • DOI
    10.1109/TBME.2005.859784
  • Filename
    1561518